The most commonly diagnosed breast cancer (BC) subtype is characterized by estrogen receptor (ER) expression. Treatment of this BC subtype typically involves modalities that either suppress the production of estrogen or impede the binding of estrgen to its receptors, constituting the basis for endocrine therapy. While many patients have benefitted from endocrine therapy with clear reduction in mortality and cancer recurrence, one of the clinical hurdles that remain involves overcoming intrinsic (de novo) or acquired resistance to endocrine therapy driven by diverse and complex changes occurring in the tumor microenvironment. Moreover, such resistance may persist even after progression through additional antiestrogen therapies thus demonstrating the importance of further investigation of mechanisms of ER modulation. Here, we discuss a number of advances that provide a better understanding of the complex mechanistic basis for resistance to endocrine therapy as well as future therapeutic maneuvers that may break this resistance.Better sleep quality has been associated with better episodic memory performance in young adults. However, the strength of sleep-memory associations in aging has not been well characterized. It is also unknown whether factors such as sleep measurement method (e.g., polysomnography, actigraphy, self-report), sleep parameters (e.g., slow wave sleep, sleep duration), or memory task characteristics (e.g., verbal, pictorial) impact the strength of sleep-memory associations. Here, we assessed if the aforementioned factors modulate sleep-memory relationships. Across age groups, sleep-memory associations were similar for sleep measurement methods, however, associations were stronger for PSG than self-report. Age group moderated sleep-memory associations for certain sleep parameters. Specifically, young adults demonstrated stronger positive sleep-memory associations for slow wave sleep than the old, while older adults demonstrated stronger negative associations between greater wake after sleep onset and poorer memory performance than the young. Collectively, these data show that young and older adults maintain similar strength in sleep-memory relationships, but age impacts the specific sleep correlates that contribute to these relationships.Individuals with mitochondrial disease often present with psychopathological comorbidity, and mitochondrial dysfunction has been proposed as the underlying pathobiology in various psychiatric disorders. Several studies have suggested that medications used to treat neuropsychiatric disorders could directly influence mitochondrial function. This review provides a comprehensive overview of the effect of these medications on mitochondrial function. We collected preclinical information on six major groups of antidepressants and other neuropsychiatric medications and found that the majority of these medications either positively influenced mitochondrial function or showed mixed effects. Only amitriptyline, escitalopram, and haloperidol were identified as having exclusively adverse effects on mitochondrial function. In the absence of formal clinical trials, and until such trials are completed, the data from preclinical studies reported and discussed here could inform medication prescribing practices for individuals with psychopathology and impaired mitochondrial function in the underlying pathology.Alzheimer's disease (AD) is the most common cause of dementia affecting millions of people. Neuronal death in AD is initiated by oligomeric amyloid-β (Aβ) peptides. The amyloid channel hypothesis readily explains the primary molecular damage but does not address major observations associated with AD such as autophagy failure and decreased metabolism. The amyloid degradation toxicity hypothesis provides the interpretation as a sequence of molecular events. Aβ enters a cell by endocytosis, and the endocytic vesicle is merged with a lysosome. Lysosomal peptidases degrade the peptide. Fragments form membrane channels in lysosomal membranes that have a significant negative charge due to the presence of acidic phospholipids. Amyloid channels can transfer various ions (including protons) and even relatively large compounds, which explains lysosomal permeabilization. The neutralization of lysosomal content inactivates degradation enzymes, results in an accumulation of undigested amyloid, and stalls autophagy. Inadequate quality control of mitochondria is associated with an increased production of reactive oxygen species and decreased energy production. Also, the passage of lysosomal proteases through rare extremely large channels results in cell death. Proposed hypothesis identifies biochemical pathways involved in the initiation and progression of cellular damage induced by beta-amyloid and provides new potential pharmacological targets to treat Alzheimer's disease.To investigate the interaction of long non-coding RNA zinc finger antisense 1 (lncRNA ZFAS1) in secondary cerebral edema (CE) and neuron injuries after traumatic brain injury (TBI) in a mouse model.
TBI mouse models was established by free-fall strike. https://www.selleckchem.com/products/ap-3-a4-enoblock.html Adeno-associated virus-short hairpin-ZFAS1 was administrated into mice via intracerebral injection to downregulate lncRNA ZFAS1. LncRNA ZFAS1 in mouse brain was examined. Neurological severity score (NSS), cerebral water content (CWC) and lesion volume were measured. The number of TUNEL-positive cells in brain tissue was accessed. Bax and cleaved caspase-3 in brain tissues were measured by western blot analysis, and pro-inflammatory factor levels were detected.
LncRNA ZFAS1 expression was upregulated in mouse brain tissues 3 days after TBI modelling. After the knockdown of lncRNA ZFAS1, NSS, CWC and lesion volume were decreased, apoptotic gene levels were decreased and pro-inflammatory cytokine levels were reduced, suggesting that lncRNA ZFAS1 knockdown could alleviate TBI-induced brain injuries in mice.
This study demonstrated that silencing lncRNA ZFAS1 inhibited TBI by quenching apoptosis, reducing inflammatory response and improving the recovery of neurological function in TBI mice. LncRNA ZFAS1 might function as a possible curative management in secondary CE and neuron injury in TBI mice.
This study demonstrated that silencing lncRNA ZFAS1 inhibited TBI by quenching apoptosis, reducing inflammatory response and improving the recovery of neurological function in TBI mice. LncRNA ZFAS1 might function as a possible curative management in secondary CE and neuron injury in TBI mice.